Bearing material

ABSTRACT

A composite material is described which will provide low friction surfaces for materials in rolling or sliding contact and is self-lubricating and oxidation resistant up to and in excess of about 930°C. The composite is comprised of a metal component which lends strength and elasticity to the structure, a fluoride salt component which provides lubrication and, lastly, a glass component which not only provides oxidation protection to the metal but may also enhance the lubrication qualities of the composite.

ORIGIN OF THE INVENTION

The invention described herein was made by an employee of the United States Government and may be manufactured or used by or for the Government without the payment of any royalties thereon or therefor.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to composite bearing materials which are self-lubricating and oxidation resistant over a broad temperature range up to and preferably in excess of about 930° C. Composites of this invention are comprised of distinct metallic, glass and fluoride components.

These novel composites may be fabricated by infiltration of a porous, sintered metal with molten glass and fluorides as is well-known in the field of powder metallurgy. Optionally, the constituents of the composite may be co-deposited by plasma-spray techniques on a suitable substrate.

2. Description of the Prior Art

Lubrication of mating surfaces in frictional engagement has long posed problems of wear (e.g., abrasive, adhesive, chemical and fatigue) and overheating of machine parts which subsequently fail prematurely as the manifest result thereof. Typically, oils and greases have been employed to mitigate the deleterious effects of heat and abrasion by virtue of their very low coefficients of friction and relatively long-life properties. However, as technology progressed and thus imposed more severe operating conditions, most notably, higher operating temperatures, it was found that the lubrication properties of fluids were inherently limited, thus ultimately limiting the scope of the advanced design.

In response to the inherent deficiencies of fluid lubricants, solid lubricants emerged as clearly superior in extreme environmental conditions such as high temperatures at which fluids decompose or, on the other hand, extremely low temperatures at which fluids freeze. Additionally, it has been shown that many solid lubricants are extremely effective in chemically active environments which readily decompose fluid lubricants via chemical attack.

Moreover, solid lubricants effect overall savings in many systems insofar as vast weight reduction can be achieved through elimination of pumps, heat exchangers, recirculation systems, and the like, as well as the elimination of seals ofttimes necessary to isolate lubricating and working fluids. Similarly, replenishment of contaminated fluids is vitiated by the use of solid lubricants.

Perhaps the first and most widely employed solid lubricant was graphite. Graphite is formed as a covalently bonded carbon solid of hexagonal structure which may be viewed microscopically as two-dimensional planar molecules occupying basal plane positions, stacked one on top of another and held together by weak, secondary van der Waals forces. The facility with which these "sheets" may readily part along basal planes provides the well-known lubrication qualities of graphite.

However, graphite possesses severe deficiencies as a lubricant in extreme conditions. It has well been demonstrated that the lubricating qualities of graphite are predicated upon its ability to adsorb gas, moisture or hydrocarbon vapors before the property of low shear strength is attained. While the gases and water vapor present in a normal atmosphere are usually sufficient to ensure an adequate supply of adsorbable material, at high altitudes or under vacuum conditions, for example, desorption occurs with the subsequent loss of lubrication features. Additionally, at temperatures over approximately 95° C., adsorption is significantly decreased with a concomitant decrease in lubrication properties.

To minimize these deficiencies, it has been shown that graphite may be reacted with fluorine gas to yield an improved solid lubricant of the form CF_(x) where x may vary from approximately 0.3 to 1.1. While this intercalation compound of graphite is capable of providing lubrication without the need of an adsorbed vapor or impurity up to temperatures of approximately 500° C., the chemical reaction must be carefully controlled to yield suitable properties. Then too, oxidation or dissociation at temperatures approaching 500° C. remain persistent problems in graphite systems regardless of the fabrication techniques or chemical alteration thereof.

Similar to graphite are such solid lubricants as molybdenum disulfide and tungsten disulfide which are also hexagonal-layered and whose shear properties are anisotrophic, with preferred easy shear parallel to the basal planes of the crystallites. In contradistinction to graphite, neither of these disulfides requires the presence of an adsorbed layer to achieve lubrication properties; however, these disulfides too are temperature limited, albeit at higher temperatures approaching 400° C. where decomposition by oxidation occurs.

Moreover, in highly oxidizing conditions it is well known that the presence of molybdenum greatly contributes to the catastrophic oxidation of many engineering alloys. This catastrophic or accelerated oxidation results as molybdenum oxidizes to MoO₃ at temperatures greater than 400° C. This oxide of molybdenum will melt at approximately 795° C., and it has been suggested that this low-melting oxide phase may then act as a flux to dislodge or dissolve protective films. Additionally, eutectic combinations of the molybdenum oxide and other oxides present will further reduce the melting point thus aggravating the structural degradation attendant this high temperature oxidation.

While the effectiveness of the above-noted layer-lattice lubricants may be greatly enhanced through resin bonding techniques, severe limitations are yet presented as temperatures increase within the range of interest. Still too the problem of catastrophic oxidation are not overcome by such resin bonding of the lubricant.

The breakthrough in high temperature lubrication came with the discovery that various fluorides provide low friction surfaces under extremes of temperatures and ambient chemical environment. Note, for example, U.S. Pats. No. 3,157,529, No. 3,419,363 and No. 3,508,955 each to H. E. Sliney and assigned to the National Aeronautics and Space Administration. Each of these patents relates generally to solid lubricants comprised of, inter alia, fluorides.

More particularly, U.S. Pat. No. 3,157,529 discloses fluoride lubricant coatings applied as a film to the surface to be lubricated, which coatings are basically comprised of calcium fluoride and a suitable ceramic binder therefor. While such techniques have proved extremely effective in the field of high-temperature solid-lubricant coatings, the useful life of such coatings is limited. When the coating eventually is worn away, the lubricant cannot be readily replenished and lubrication ceases. A method whereby solid lubricant is replenished as wear takes place is clearly desirable. Self-lubricating composites are an approach to accomplish this replenishment.

To reduce the problems of film-type solid lubricants, composite bearing materials containing fluoride lubricants were subsequently developed by Sliney. For example U.S. Pat. No. 3,419,363 discloses such a composite comprised of a porous metal impregnated with Group I or Group II metallic fluorides with the eutectic composition of barium fluoride and calcium fluoride as the preferred lubricant. However, such composites have posed new problems insofar as the porous metal component provides a greatly increased surface area as opposed to that of solid substrates. Accordingly, high temperature oxidation of these porous, sintered metals poses significant problems at temperatures exceeding about 700° C.

Accordingly, a need exists for improved high-temperature, self-lubricating materials which exhibit the excellent lubricating qualities of fluoride-containing composites and yet are not susceptible to high temperature oxidation. The need for such materials is presently becoming critical in advanced aircraft where aerodynamic heating at speeds of Mach 3 and higher can result in vehicle skin temperatures well above the temperature limitations of presently available air frame bearings. As an extreme case, it is predicted that the maximum skin temperature for the Space Shuttle Orbitor during re-entry will approach or exceed 1100° C. Air frame bearings and control surface seals for the orbitor proximate these heated surfaces must be capable of high temperature operation without degradation. Other areas in which high temperature lubrication has become increasingly more important include sliding contact seals for automotive turbine regenerators, shaft seals for turbo pumps, piston rings for high performance reciprocating compressors, hot glass processing machinery, and the like.

SUMMARY OF THE INVENTION

To obviate the deficiencies in the prior art, it is the primary object of this invention to provide self-lubricating bearing materials which are oxidation-resistant up to and preferably in excess of about 930° C.

It is also an object of this invention to provide self-lubricating, oxidation-resistant bearing materials comprised of a heat-resistant metal component, an oxidation-inhibiting glass component and a lubricating fluoride component.

It is yet another object of this invention to provide these self-lubricating, oxidation-resistant bearing materials fabricated either by infiltrating a porous, sintered metal body with molten glass and fluoride or by plasma-spray co-deposition of the metal, glass and fluoride components.

It is still a further object of this invention to provide self-lubricating, oxidation-resistant bearing materials which are durable and yield plastically under unit loads of at least 35 MN/m² at temperatures up to and in excess of about 930° C.

It is another object of this invention to fabricate self-lubricating, oxidation-resistant bearing materials simpy, yet efficiently, and at low cost.

Further objects of this invention will become apparent to those skilled in the art from examination of the following detailed description of the invention.

It has now been determined in accordance with this invention that low friction surfaces exhibiting self-lubrication and oxidation resistance up to and in excess of about 930° C. may be formed as a composite of a metallic constituent which lends strength and elasticity to the structure, a glass component which provides oxidation protection to the metal and may also contribute to reduced wear and, finally, a fluoride component which provides lubrication. The composite of this invention may be fabricated as a porous, sintered metallic matrix which is infiltrated with molten glass and fluoride or, optionally, a suitable substrate with metal, glass, and fluoride components co-deposited thereon by plasma-spray techniques. The lubricating material of the present invention will effectively preclude galling from room temperature to and in excess of 930° C., but is particularly effective over the range 530°-930° C. at which temperature the glass and particularly the fluorides are soft enough to form a smear or glaze of lubricating film on the surface. These novel composites are easily machined and exhibit plastic response over the temperature range of interest.

DETAILED DESCRIPTION OF THE INVENTION

The principle of operation of the self-lubricating, oxidation-resistant composites of the invention rests upon the ability of the metallic content of the composite to provide strength and elasticity to the structure; the glass will provide oxidation-protection to the metal and may additionally enhance the lubrication quality of the fluoride component. During the sliding process, any wear that takes place exposes more fluoride lubricant thereby preventing an increase in wear rate or galling of the surfaces. The lubricating material will effectively prevent galling from room temperature to at least 930° C., but it is particularly effective from 530° to 930° C. at which temperatures the glass and particularly the fluorides are soft enough to form a smear or glaze of lubricating film on the surface.

As noted above, the function of the metallic component is to provide structural strength to the instant composites over the temperature range of interest and under bearing loads which oftentimes exceed unit stresses of approximately 35 MN/m². Accordingly, this metal component may be selected from any of the well known high temperature alloys, and most notably alloys of iron, cobalt or nickel. Specific examples of such high temperature alloys which may be used to fabricate the composites of the instant invention are: for iron -- austenitic and ferritic stainless steels, for example; for cobalt -- super-alloys containing significant chromium such as H.S.6B, H.S. 21, and H.S.25; and for nickel -- super-alloys such as the Inconels, nichromes, Rene 41, and the like. Numerous other high temperature alloys are equally well suited to provide the necessary structural strength at the temperatures of interest and are familiar to those skilled in the art. However, it has been determined that the metal component of the composite is preferably a high nickel or cobalt alloy, i.e., one containing greater than 50% nickel or cobalt, with significant chromium content, i.e., greater than 10%. Most preferred is an 80% nickel, 20% chromium alloy.

Optionally, the metallic component of the composite may contain silver, gold or alloys thereof, it being understood that the optional silver additions limit the maximum serviceable temperature to about 820° C. as the result of a melting point of about 850° C. for this component. Such additions will improve the low temperature lubricating characteristics of the composite thereby expanding their effective operating range. While these silver and/or gold additions may be present from 0 to 50% by weight, it will be appreciated that the time-temperature profile for the composite bearing material will necessarily predicate the amounts of these components, particularly the relatively low melting silver. Accordingly, bearings which are put into prolonged, high-temperature service, i.e., more than approximately 90% of their operating time at temperatures in excess of approximately 500° C. need incorporate only minor percentages of precious metal components such as 0 to 10%. Contrariwise, bearings expected to be subjected to short-lived, rapid fluctuations up to high temperatures of approximately 900° C. but typically operated within an ambient temperature range of about room temperature to 500° C. may incorporate significant percentages of these silver and/or gold additions, i.e., 10 to 50%. Accordingly, it can readily be seen that the instant composites may be tailored to meet numerous design criteria.

Turning now to the fluoride component of the self-lubricating composites, it will be appreciated that numerous fluoride salts may be employed to achieve the desired lubrication features. Illustrative of such fluoride salts are those of Group I and Group II metals of the Periodic Table of Elements as well as fluorides of rare earth (lanthanide series) metals of the Periodic Table of Elements. Preferred for providing the lubricating qualities of the composites of this invention are eutectic mixtures of the foregoing fluorides. Also preferred are the fluorides of calcium and barium, while most preferred is the eutectic composition of calcium fluoride and barium fluoride.

With regard to the glass component of the topic composites, it has been determined to be highly beneficial to employ a silicate glass [i.e., a glass containing from 55% to 80% silica] which is high in concentration, [i.e., at least about 20% by weight] of oxides of divalent ions of Group II metals, especially Ba⁺ ⁺, and low [i.e., less than about 10% by weight] in oxides of monovalent ions of Group I metals such as and Na⁺. That is, it is most beneficial to employ Group II silicate network modifiers in preferance to the more conventionally employed Group I modifiers found typically in commercial glasses such as the common soda-glasses. Such a constraint may be explained, at least in part, by the observation that glasses low in Na⁺ content have an atomic arrangement which is less favorable for diffusion of transition metal ions such as Fe⁺ ⁺, Co⁺ ⁺, Ni⁺ ⁺, and Cr⁺ ⁺ ⁺. Accordingly, these low sodium ion glasses will provide better protection of the metallic constituents of the composite against oxidation reactions such as these which are diffusion-rate controlled.

A preferred glass composition within the scope of the instant invention is comprised of 10 to 50% BaO; 0 to 30% Na₂ O and/or K₂ O; 0 to 15% CaO; and, balance SiO₂. While it has been determined that glasses falling within the foregoing preferred compositional limits will effectively inhibit oxidation of the metallic component of the composite, the most preferred glass composition is one comprised of 20% BaO, 10% K₂ O, 10% CaO, 60% SiO₂.

Having thus described the individual components of the topic self-lubricating, oxidation-resistant composites of the present invention, it will be appreciated that each of the metal, fluoride, and glass components may be present in varying amounts. For example, in view of the fact that the metallic component of the composite is fundamentally present to provide structural integrity, bearing surfaces subjected to fairly low loads, i.e., 7 MN/m² or less, may function adequately with a metallic content of from 20 to 40% relative to the weight of the entire composite. Contrariwise, bearing surfaces subjected to high unit loads, i.e., loads above 35 MN/m² may require as much as 80% metallic constituent to provide the necessary structural strength. Accordingly, the skilled artisan may incorporate the metallic component in amounts ranging from 20 to 80% depending upon the design criteria for the desired application. Similarly, depending upon the degree of oxidation-inhibition desired when viewed against the oxidizing nature of both the ambient environmental and metal component selected, the combined glass and fluoride salt content may be present within the range of 20 to 80%.

With regard to this combined fluoride salt and glass content, the fluoride-to-glass ratio may extend from 1:2 to 2:1. Should the ambient surroundings of the composite bearing material be highly oxidizing, there may be provided up to two-thirds oxide-inhibiting glass relative to the fluoride salt content while less oxidizing atmospheres may allow for as low as one-third glass content relative to the fluoride component of the composite. However, under most circumstances, the most preferred ratio between fluoride salt content and glass content is 1:1.

Accordingly, in view of the foregoing, self-lubricating, oxidation-resistant bearing composites may be comprised of from 20 to 80% high-temperature resistant metallic component; 0 to 50% silver, gold or alloys thereof; and, 20 to 80% combined lubricating fluorides and oxide-inhibiting glass. A preferred composition comprises 60 to 70% of a metallic constituent selected from the group of high temperature iron, cobalt and nickel alloys; 15 to 20% of a lubricating fluoride salt selected from the group of calcium fluoride, barium fluoride and mixtures thereof; and, 15 to 20% of a glass comprised of from 10 to 50% barium oxide, 0 to 30% sodium oxide and/or potassium oxide, 0 to 15% calcium oxide and balance silica.

A most preferred composite according to the present invention is comprised of 67% of an 80 nickel, 20 chrome alloy, 161/2% of barium fluoride-calcium fluoride eutectic, and 161/2% of a glass comprised of 20% BaO, 10% K₂ O, 10% CaO, and 60% SiO₂. In the case of plasma-sprayed composites, the fluoride eutectic may be replaced with the single fluoride, CaF₂.

Having thus described the materials which may be employed to fabricate the composites of the present invention as well as clearly setting forth the most preferred composition, the present invention will be described with reference to the following two fabrication techniques for the subject bearing material.

INFILTRATION OF POROUS, SINTERED METAL WITH MOLTEN OXIDATION-INHIBITING GLASS AND LUBRICATING FLUORIDES

Composites within the ambit of the present invention may adequately be fabricated according to well known powder metallurgy techniques with respect to infiltration of porous, sintered metal components. For example, the porous metal may be fabricated from powders of from -100 mesh to -200 mesh which are hydrostatically pressed at approximately 130 MN/m² to 150 MN/m² and then sintered in hydrogen for 1 to 11/2 hours at from about 1150° to 1180° C. Typically, for the metal systems described above, this will result in a porous metal body of approximately 65% density with pore diameters in the range of approximately 25 to 35 microns.

These porous metal bodies are thence subjected to a double infiltration procedure whereby the pores are first partially filled with glass which, by its wetting action coats the walls of the metallic pore structure. This glass infiltration is achieved by disposing the porous, sintered metal component in a metal container with the desired quantity of glass completely covering the metal workpiece. The container is then evacuated and subsequently backfilled with argon gas to a pressure of about 10 microns to provide an inert atmosphere. The container is heated to a temperature of from 1150° C. to 1180° C. Such a treatment is continued for 1/2 to 1 hour to insure complete impregnation of the glass within the workpiece.

The glass infiltrated, metal workpiece is then cooled and removed to a second container wherein it is contacted with the desired fluoride component which is present slightly in excess of the amount necessary to completely fill the remaining void spaces. Once again, the container is evacuated, but to a pressure no lower than 1 micron to prevent evaporation of the fluoride component. A second infiltration of fluoride salt is then conducted in the evacuated container and at a lower temperature than the first in order to minimize the solution of the glass into the molten fluoride, said second infiltration being carried out at from 1035° C. to 1050° C. Fluoride infiltration proceeds basically by capillary action; however, to ensure complete impregnation of the metal workpiece, an inert gas may optionally be introduced at a slight positive pressure of approximately 7 × 10 N/m² to force any residual, molten fluoride into any remaining void space subsequent to the vacuum infiltration.

The composites are then cooled in an inert gas atmosphere, removed from the infiltration apparatus, and wet sanded to remove excessive fluoride adhering to the workpiece. Optionally, a thin coating of fluoride eutectic, selected from those fluoride salts enumerated hereinabove, may then be applied to thereby fill any microscopic pores remaining on the surface and to enrich the surface with the lubricating component. This will not only ensure a uniform bearing surface but, additionally, reduce areas of stress concentration as a result of surface microcracks and/or microvoids. Application of the fluoride overcoat may be achieved by spraying or by painting as a water suspension, and then heat-bonding at about 950° C. in an argon or other inert atmosphere.

Also optionally, up to 35% silver, gold or alloys thereof may be added to the solids content of the thin fluoride spray coating. Such additives aid in reducing friction and wear at temperatures below about 500° C. without interfering with fluoride lubrication at higher temperatures. Should it be desired, the precious metals enumerated hereinabove may be applied alone by electroplating from a suitable bath onto the surface of the composite.

PLASMA SPRAY CODEPOSITION

The preferred fabrication technique of the present invention invisions the formation of the self-lubricating composite from plasma sprayed metal- glass-fluoride powders. Numerous important advantages are attained from employing plasma-arc spray techniques as opposed to the aforementioned infiltration of porous sintered bodies. Most notably, the plasma-spray codeposition of the various constituents of this composite directly upon the supporting substrate precludes the necessity of the additional process step of brazing or otherwise attaching the lubricating composite to the desired surface. With respect to this additional step of brazing, etc. which typically requires heating the substrate into a temperature range possibly harmful to the metallurgical properties thereof, the plasma-spray technique need not heat the substrate over approximately 150° C. thus preserving the effects of any prior heat treatment, reducing the possibility of alloy segregation, etc. Additionally, the plasma-spray technique is simpler, more economical and faster than impregnation of porous, sintered metal workpieces.

In carrying out the plasma-spray method, glass frit is prepared in any manner well known to those skilled in the art; e.g., ball milling a suitable glass composition. The glass frit is sized to particles of 125 microns and is thence mixed with the desired metal powder and fluoride lubricant powder.

The underlying substrate surface upon which the bearing composite is to be codeposited should be grit blasted or otherwise cleaned to remove surface films, foreign materials and the like. The composites may then be sprayed to a thickness from 0.010 centimeters to 0.060 centimeters and subsequently machined back to a working thickness of from approximately 0.005 centimeters to approximately 0.050 centimeters.

Techniques employed for such plasma-arc codeposition are well known in the prior art. Note, for example, U.S. Pats. No. 3,540,942 and No. 3,640,755, each of which deals with conceptually similar techniques for the plasma-arc spraying of metallic materials. More particularly, note NASA Technical Memorandum TMX-71432, "Plasma-Sprayed Metal-Glass and Metal-Glass Fluoride Coatings for Lubrication to 900° C." by H. E. Sliney, incorporated herein by reference, and relied upon. It will be appreciated, however, that other metal-spray techniques may likewise be employed to achieve the codeposition of the metal- glass-fluoride constituents of the topic composites. Such other techniques, as are obvious to those skilled in the art, include, for example, flame-spray and electric-arc spray such as set forth in Manufacturing Processes and Materials for Engineers, Doyle et al, 2nd Edition, Prentice Hall, New Jersey, 1961, pages 376-378.

Regardless of the fabrication technique selected from those mentioned above, the composite bearing materials of this invention may be surface enriched in the lubricant by a thin fluoride spray film as previously described or by subsequent heat treatment in air at from 760° C, to 900° C. for 4 to 24 hours. Such a heat treatment will cause slight exudation and solid state migration of fluorides along the surface and further serves the beneficial purpose of milding pre-oxidizing the exposed metal. Additionally, the surfaces will become entirely covered with a combined fluoride-oxide film which is highly desirable to prevent direct metal-to-metal adhesive contact during sliding.

Additionally, it should be noted that the self-lubricating, oxidation-resistant composites of this invention are easily machinable and may be put into service as machined, as honed, or finished with abrasive paper. Under bearing loads of 35 MN/m² or greater and at temperatures up to at least 930° C. these composites will yield plasticly thus precluding failures due to brittle fracture and reducing fatigue tendencies attendant high-cycle operation typical of bearing applications.

To further illustrate the objects and advantages of the present invention, the following specific examples will be given, it being understood that same are intended to be merely illustrative and in no wise limitative.

EXAMPLE 1

80 grams of AISI 310 heat-resistant stainless steel powder of -100 mesh are isostatically pressed at 140 MN/m² and sintered in hydrogen for 1 hour at 1175° C. to yield a porous workpiece of approximately 65% theoretical density with pore sizes varying from approximately 25 to 35 microns. This porous metal component is then disposed in a vacuum/induction furnace to which is also added 15 grams of glass comprised of 15% barium oxide, 10% calcium oxide and 70% silica. The furnace is then evacuated, backfilled with argon, and heated to 1180° C. for 1/2 hour to effect infiltration of the glass within the pores of the metal workpiece. The impregnated workpiece is then cooled and removed to a second vacuum/induction furnace to which is also added slightly more than 5 grams of fluoride salt composed of the eutectic mixture of calcium fluoride and barium fluoride. This furnace is then evacuated to 5 microns and heated to 1050° C. for 1/2 hour to complete the impregnation procedure. The composite is cooled to room temperature in the furance in an argon atmosphere removed and wet sanded to remove excess fluoride.

EXAMPLES 2 - 7

Examples 2 - 7 are prepared in the same manner as that described in Example 1. Materials for Examples 2 - 7 are indicated in the appropriate columns of Table 2 and are chosen from the specific materials enumerated in Table 1.

EXAMPLE 8

60 grams of Haynes Stellite 6B powder and 10 grams of silver, each of -125 mesh, are combined with 15 grams of glass frit of 125 microns prepared by ball milling 20% barium oxide, 10% potassium oxide, 10% calcium oxide and 60% silicon oxide; and, 15 grams of calcium fluoride -- barium fluoride eutectic powder. This mixture is plasma-arc sprayed on an AISI 440C stainless substrate which is prepared by grit blasting to remove any foreign matter. The metal, glass and fluoride composite is co-deposited to a thickness of 0.050 centimeters and allowed to cool. The composite is then honed to a thickness of 0.025 centimeters and is ready for service.

EXAMPLES 9 - 14

Examples 9 - 14 are prepared in the same manner as that given for Example 8 and are composed of those materials outlined in Table 2, which materials are selected from those set forth in Table 1.

                                      TABLE 1                                      __________________________________________________________________________     Metal:                                                                               A     B     C     D       E        F                                           AISI 310                                                                             AISI 330                                                                             H.S. 6B                                                                              Hastelloy G                                                                            80% Ni, 20% Cr                                                                          Incoloy                               __________________________________________________________________________     Glass:                                                                          BaO  10    15    20    25      30       35                                     Na.sub.2 O                                                                          --    --    --    --      5        5                                      K.sub.2 O                                                                           --    --    10    5       5        5                                      CaO  10    10    10    5       0        0                                      SiO.sub.2                                                                           80    75    60    65      60       55                                    Fluorides:                                                                      CaF.sub.2                                                                           100   --     50*  50      50       --                                     BaF.sub.2                                                                           --    100   50    --      --       --                                     MgF.sub.2                                                                           --    --    --    --      --       60                                     LiF  --    --    --    --      50       40                                     SrF.sub.2                                                                           --    --    --    50      --       --                                    __________________________________________________________________________      *eutectic                                                                

                  TABLE 2                                                          ______________________________________                                         Example                                                                               Method*  Metal         Glass  Fluoride                                  ______________________________________                                         1      I        80% A         15% B   5% C                                     2      I        60% E         20% B  20% C                                     3      I        80% E         20% C   0                                        4      I        30% C         30% D  40% C                                     5      I        80% C         10% C  10% A                                     6      I        60% B         20% C  20% E                                     7      I        65% A         15% C  20% F                                     8      II       60% C + 10% Ag                                                                               15% C  15% C                                     9      II       30% E + 30% Ag                                                                               15% C  25% A                                     10     II       30% C + 30% Ag                                                                               15% C  25% A                                     11     II       67% E         161/2% C                                                                              161/2% A                                  12     II       70% A         20% D  10% C                                     13     II       40% D         20% B  40% B                                     14     II       80% E         20% E   0                                        ______________________________________                                          *I -- infiltration                                                             II -- plasma-spray                                                       

While the invention has been described and illustrated with reference to certain preferred embodiments thereof, those skilled in the art will appreciate that various modifications, changes, omissions and substitutions may be made without departing from the spirit of the invention. It is intended, therefore, that the invention be limited only by the scope of the following claims. 

What is claimed is:
 1. A self-lubricating, oxidation-resistant composition of matter comprising:a. a metal component capable of providing strength and elasticity to a temperature up to and in excess of about 930° C.; b. a fluoride salt component capable of providing lubrication; and c. a glass component capable of inhibiting oxidation of said metal component.
 2. The self-lubricating, oxidation-resistant composition of matter according to claim 1, wherein said fluoride salt component is selected from the group consisting of the fluorides of:a. Group I metals; b. Group II metals; c. Rare earth (lanthanide series) metals; and, d. mixtures thereof.
 3. The self-lubricating, oxidation-resistant composition of matter according to claim 1, wherein said glass component comprises a silicate glass containing at least about 20% of divalent cations.
 4. The self-lubricating, oxidation-resistant composition of matter according to claim 1, wherein said metal component comprises:a. 20 to 80 weight percent iron, cobalt, or nickel alloy; and b. 0 to 50 weight percent silver, gold, or an alloy thereof.
 5. The self-lubricating, oxidation-resistant composition of matter according to claim 1, wherein said fluoride salt component and said glass component are present in a combined amount of 20 to 80 weight percent based upon the total weight of the composition.
 6. The self-lubricating, oxidation-resistant composition of matter according to claim 1, wherein said metal component is present in an amount of 20 to 80 weight percent based upon the total weight of the composition.
 7. The self-lubricating, oxidation-resistant composition of matter according to claim 1, wherein said fluoride salt component and said glass component are present in a ratio between about 1:2 and 2:1 by weight.
 8. The self-lubricating, oxidation-resistant composition of matter according to claim 7, wherein said fluoride salt component and said glass component are present in the ratio of about 1:1 by weight.
 9. The self-lubricating, oxidation-resistant composition of matter according to claim 1, wherein:a. said metal component comprises 80% nickel and 20% chromium; b. said fluoride salt component is selected from calcium fluoride, barium fluoride and mixtures thereof; and said glass component comprises 10 to 50% barium oxide; 0 to 20% sodium oxide, potassium oxide, or mixtures thereof; 0 to 10% calcium oxide; and balance silicone oxide.
 10. A shaped, self-lubricating member comprising the composition as defined by claim
 1. 11. A self-lubricating member comprising a solid substrate bearing a coating of the composition as defined by claim
 1. 12. The self-lubricating, oxidation-resistant composition of matter according to claim 1, wherein said metal component, said fluoride salt component and said glass component constitute an intimate admixture. 